Metadata-Version: 2.1
Name: dyneusr
Version: 0.3.6
Summary: Dynamical Neural Spatiotemporal Representations.
Home-page: https://braindynamicslab.github.io/dyneusr
Author: Caleb Geniesse
Author-email: geniesse@stanford.edu
License: BSD-3
Description: 
        
        <p align="center">
        <a href="https://braindynamicslab.github.io/dyneusr/">
        <img src="https://raw.githubusercontent.com/braindynamicslab/dyneusr/master/docs/assets/logo.png" height="250">
        </a>
        </p>
        
        
        <p align="center">
        <a href="https://braindynamicslab.github.io/dyneusr/">
        <img src="https://raw.githubusercontent.com/braindynamicslab/dyneusr/master/docs/assets/haxby_decoding_mapper_stages.png">
        </a>
        </p>
        
        
        
        ## **Dynamical Neuroimaging Spatiotemporal Representations**
        
        [![https://www.singularity-hub.org/static/img/hosted-singularity--hub-%23e32929.svg](https://www.singularity-hub.org/static/img/hosted-singularity--hub-%23e32929.svg)](https://singularity-hub.org/collections/4218)
        
        [DyNeuSR](https://braindynamicslab.github.io/dyneusr/) is a Python visualization library for topological representations of neuroimaging data.
        
        DyNeuSR was designed specifically for working with shape graphs produced by the Mapper algorithm from topological data analysis (TDA), as described in the papers "[Generating dynamical neuroimaging spatiotemporal representations (DyNeuSR) using topological data analysis](https://www.mitpressjournals.org/doi/abs/10.1162/netn_a_00093)" (Geniesse et al., 2019) and "[Towards a new approach to reveal dynamical organization of the brain using topological data analysis](https://www.nature.com/articles/s41467-018-03664-4)" (Saggar et al., 2018). Check out this [blog post](https://bdl.stanford.edu/blog/tda-cme-paper/) for more about the initial work that inspired the development of DyNeuSR. 
        
        Developed with neuroimaging data analysis in mind, DyNeuSR connects existing implementations of Mapper (e.g. [KeplerMapper](https://kepler-mapper.scikit-tda.org)) with network analysis tools (e.g. [NetworkX](https://networkx.github.io/)) and other neuroimaging data visualization libraries (e.g. [Nilearn](https://nilearn.github.io/)) and  provides a high-level interface for interacting with and manipulating shape graph representations of neuroimaging data and relating these representations back to neurophysiology.
        
        DyNeuSR also provides an interactive web interface for visualizing and exploring shape graphs. To see this visual interface in action, check out the [demos](https://braindynamicslab.github.io/dyneusr/demo/).
        
        
        
        
        ## **Demos**
         
        - [Trefoil knot](https://braindynamicslab.github.io/dyneusr/demo/trefoil-knot/) ([code](https://github.com/braindynamicslab/dyneusr/blob/master/docs/demo/trefoil-knot/trefoil_knot.py))
        - [Trefoil knot (custom layouts)](https://braindynamicslab.github.io/dyneusr/demo/trefoil-knot/) ([code](https://github.com/braindynamicslab/dyneusr/blob/master/docs/demo/trefoil-knot-custom-layouts/trefoil_knot_custom_layouts.py))
        - [Haxby fMRI data (t-SNE lens)](https://braindynamicslab.github.io/dyneusr/demo/haxby-tsne/) ([code](https://github.com/braindynamicslab/dyneusr/blob/master/docs/demo/haxby-tsne/haxby_tsne.py))
        - [Haxby fMRI data (UMAP lens)](https://braindynamicslab.github.io/dyneusr/demo/haxby-umap/) ([code](https://github.com/braindynamicslab/dyneusr/blob/master/docs/demo/haxby-umap/haxby_umap.py))
        - [Haxby fMRI data (supervised UMAP lens)](https://braindynamicslab.github.io/dyneusr/demo/haxby-umap-supervised/) ([code](https://github.com/braindynamicslab/dyneusr/blob/master/docs/demo/haxby-umap-supervised/haxby_umap_supervised.py))
        
        
        ## **Related Projects** 
        
        - [DyNeuSR Fire](https://braindynamicslab.github.io/dyneusr-fire/) is a new project that provides a command line interface for DyNeuSR. It wraps `kmapper` and `dyneusr` into a single pipeline, and uses the [Python Fire](https://github.com/google/python-fire) library to automatically generate a simple command line interface that accepts several important options and allows users to customize this pipeline. For more information about DyNeuSR Fire, check out the [docs](https://braindynamicslab.github.io/dyneusr-fire/).
        
        
        ## **References**
        
        If you find DyNeuSR useful, please consider citing:
        
        > Geniesse, C., Sporns, O., Petri, G., & Saggar, M. (2019). [Generating dynamical neuroimaging spatiotemporal representations (DyNeuSR) using topological data analysis](https://www.mitpressjournals.org/doi/abs/10.1162/netn_a_00093). *Network Neuroscience*. Advance publication. doi:10.1162/netn_a_00093
        
        
        For more information about the Mapper approach, please see:
        
        > Saggar, M., Sporns, O., Gonzalez-Castillo, J., Bandettini, P.A., Carlsson, G., Glover, G., & Reiss, A.L. (2018). [Towards a new approach to reveal dynamical organization of the brain using topological data analysis](https://www.nature.com/articles/s41467-018-03664-4). *Nature Communications, 9*(1). doi:10.1038/s41467-018-03664-4
        
        
        
        
        
        ## **API Usage & Examples**
        
        DyNeuSR provides a Python API for working with and visualizing shape graphs generated by Mapper. This repository includes several [examples](https://github.com/braindynamicslab/dyneusr/tree/master/examples/) that introduce DyNeuSR's API and highlight different aspects of analysis with DyNeuSR. For more detailed tutorials, check out [dyneusr-notebooks](https://github.com/braindynamicslab/dyneusr-notebooks/).
        
        
        ### **_Shape Graph Visualization_** ([trefoil knot](https://github.com/braindynamicslab/dyneusr/blob/master/examples/trefoil_knot/trefoil_knot.py))
        
        ```python
        
        from dyneusr import DyNeuGraph
        from dyneusr.datasets import make_trefoil
        from dyneusr.tools import visualize_mapper_stages
        from kmapper import KeplerMapper
        
        # Generate synthetic dataset
        dataset = make_trefoil(size=100)
        X = dataset.data
        y = dataset.target
        
        # Generate shape graph using KeplerMapper
        mapper = KeplerMapper(verbose=1)
        lens = mapper.fit_transform(X, projection=[0])
        graph = mapper.map(lens, X, nr_cubes=6, overlap_perc=0.2)
        
        # Visualize the shape graph using DyNeuSR's DyNeuGraph                          
        dG = DyNeuGraph(G=graph, y=y)
        dG.visualize('dyneusr_output.html')
        
        ```
        
        <p align="center"><a href="https://github.com/braindynamicslab/dyneusr/tree/master/examples/trefoil_knot">
        <img src="https://raw.githubusercontent.com/braindynamicslab/dyneusr/master/docs/assets/dyneusr_trefoil_knot.png">
        </a></p>
        
        
        
        ### **_Mapper Parameter Comparison_** ([trefoil knot](https://github.com/braindynamicslab/dyneusr/blob/master/examples/trefoil_knot/compare_lenses.py))
        
        ```python
        # Define projections to compare
        projections = ([0], [0,1], [1,2], [0, 2])
        
        # Compare different sets of columns as lenses
        for projection in projections:
        
        	# Generate shape graph using KeplerMapper
        	mapper = KeplerMapper(verbose=1)
        	lens = mapper.fit_transform(X, projection=projection)
        	graph = mapper.map(lens, X, nr_cubes=4, overlap_perc=0.3)
        
        	# Visualize the stages of Mapper
        	fig, axes = visualize_mapper_stages(
        		dataset, lens=lens, graph=graph, cover=mapper.cover, 
        		layout="spectral")
        		
        ```
        
        <p align="center"><a href="https://github.com/braindynamicslab/dyneusr/tree/master/examples/trefoil_knot">
        <img src="https://raw.githubusercontent.com/braindynamicslab/dyneusr/master/docs/assets/trefoil_knot_mapper_lens_0.png">
        <img src="https://raw.githubusercontent.com/braindynamicslab/dyneusr/master/docs/assets/trefoil_knot_mapper_lens_0_1.png">
        <img src="https://raw.githubusercontent.com/braindynamicslab/dyneusr/master/docs/assets/trefoil_knot_mapper_lens_0_2.png">
        <img src="https://raw.githubusercontent.com/braindynamicslab/dyneusr/master/docs/assets/trefoil_knot_mapper_lens_1_2.png">
        </a></p>
        
        
        
        ### **_Neuroimaging Applications_** ([haxby decoding](https://github.com/braindynamicslab/dyneusr/tree/master/examples/haxby_decoding))
        
        ```python
        
        import numpy as np 
        import pandas as pd
        
        from nilearn.datasets import fetch_haxby
        from nilearn.input_data import NiftiMasker
        
        from kmapper import KeplerMapper, Cover
        from sklearn.manifold import TSNE
        from sklearn.cluster import DBSCAN
        
        # Fetch dataset, extract time-series from ventral temporal (VT) mask
        dataset = fetch_haxby()
        masker = NiftiMasker(
            dataset.mask_vt[0], 
            standardize=True, detrend=True, smoothing_fwhm=4.0,
            low_pass=0.09, high_pass=0.008, t_r=2.5,
            memory="nilearn_cache")
        X = masker.fit_transform(dataset.func[0])
        
        # Encode labels as integers
        df = pd.read_csv(dataset.session_target[0], sep=" ")
        target, labels = pd.factorize(df.labels.values)
        y = pd.DataFrame({l:(target==i).astype(int) for i,l in enumerate(labels)})
        
        # Generate shape graph using KeplerMapper
        mapper = KeplerMapper(verbose=1)
        lens = mapper.fit_transform(X, projection=TSNE(2))
        graph = mapper.map(lens, X, cover=Cover(20, 0.5), clusterer=DBSCAN(eps=20.))
        
        # Visualize the shape graph using DyNeuSR's DyNeuGraph                          
        dG = DyNeuGraph(G=graph, y=y)
        dG.visualize('dyneusr_output.html')
        
        ```
        
        <p align="center"><a href="https://github.com/braindynamicslab/dyneusr/tree/master/examples/haxby_decoding">
        <img src="https://raw.githubusercontent.com/braindynamicslab/dyneusr/master/docs/assets/dyneusr_haxby_decoding.png">
        </a></p>
        
        
        
        ## **Setup**
        
        ### **_Dependencies_**
        
        #### [Python 3.6](https://www.python.org/)
        
        #### Required Python Packages
        * [numpy](www.numpy.org)
        * [pandas](pandas.pydata.org)
        * [scipy](www.scipy.org)
        * [scikit-learn](scikit-learn.org)
        * [matplotlib](matplotlib.sourceforge.net)
        * [seaborn](stanford.edu/~mwaskom/software/seaborn)
        * [networkx](networkx.github.io)
        * [nilearn](nilearn.github.io)
        * [kmapper](kepler-mapper.scikit-tda.org)
        
        _For a full list of packages and required versions, see [`requirements.txt`](https://github.com/braindynamicslab/dyneusr/blob/master/requirements.txt) and [`requirements-versions.txt`](https://github.com/braindynamicslab/dyneusr/blob/master/requirements-versions.txt)._
        
        
        ### **_Install with PIP_**
        
        _To install with pip:_
        ```bash
        pip install dyneusr
        ```
        
        _To install from source:_
        ```bash
        git clone https://github.com/braindynamicslab/dyneusr.git
        cd dyneusr
        
        pip install -r requirements.txt
        pip install -e .
        
        pytest
        ```
        
        
        ### **_Install with Conda_**
        
        If your default environment is Python 2, we recommend that you install `dyneusr` in a separate Python 3 environment. You can find more information about creating a separate environment for Python 3 [here](https://salishsea-meopar-docs.readthedocs.io/en/latest/work_env/python3_conda_environment.html). 
        
        If you don't have conda, or if you are new to scientific python, we recommend that you download the [Anaconda scientific python distribution](https://store.continuum.io/cshop/anaconda/). 
        
        _To create a new conda environment and install from source:_
        ```bash
        conda create -n dyneusr python=3.6
        conda activate dyneusr
        
        git clone https://github.com/braindynamicslab/dyneusr.git
        cd dyneusr
        
        conda install --file requirements-conda.txt
        pip install -e .
        
        pytest
        ```
        
        This creates a new conda environment `dyneusr` and installs in it the dependencies that are needed. To access it, use the `conda activate dyneusr` command (if your conda version >= 4.4) and use `source activate dyneusr` command (if your conda version < 4.4).
        
        ### **_Run in a Singularity Container_**
        To run dyneusr in a Singularity container, for use on clusters where you do not have root access for example, first install singularity. Then, you can use the following command:
        ```
        singularity run shub://braindynamicslab/dyneusr
        source activate neuro
        ```
        This will download and run a singularity container from [singularity-hub](https://singularity-hub.org/) running centos 7 with dyneusr, jupyter, and all dependencies. It will also activate the conda environement `neuro` where these are installed. For more information on how to use singularity, see the [documentation](https://sylabs.io/docs/). The singularity recipe for this file was built with [neurodocker](https://github.com/ReproNim/neurodocker)
        
        ## **Support**
        
        Please feel free to [report](https://github.com/braindynamicslab/dyneusr/issues/new) any issues, [request](https://github.com/braindynamicslab/dyneusr/issues/new) new features, or [propose](https://github.com/braindynamicslab/dyneusr/compare) improvements. You can also contact Caleb Geniesse at geniesse [at] stanford [dot] edu.
        
        If you contribute to DyNeuSR, please feel free to add your name to the [list of contributors](https://github.com/braindynamicslab/dyneusr/blob/master/contributors.md). 
        
        ## **Citation**
        
        > Geniesse, C., Sporns, O., Petri, G., & Saggar, M. (2019). [Generating dynamical neuroimaging spatiotemporal representations (DyNeuSR) using topological data analysis](https://www.mitpressjournals.org/doi/abs/10.1162/netn_a_00093). *Network Neuroscience*. Advance publication. doi:10.1162/netn_a_00093
        
Keywords: brain dynamics,topology data analysis,neuroimaging,brain networks,mapper,visualization
Platform: UNKNOWN
Classifier: Intended Audience :: Science/Research
Classifier: Topic :: Scientific/Engineering :: Information Analysis
Classifier: Topic :: Scientific/Engineering :: Visualization
Classifier: License :: OSI Approved :: BSD License
Classifier: Operating System :: OS Independent
Classifier: Programming Language :: Python :: 3
Classifier: Programming Language :: Python :: 3.6
Classifier: Programming Language :: Python :: 3.7
Requires-Python: >=3.6
Description-Content-Type: text/markdown
